Abstract: A method forms patterns on a substrate by exposing the substrate a first time and exposing the substrate a second time using a mask containing gray-tone features. The gray-tone features locally adjust an exposure dose in regions corresponding to features defined in the primary exposure. Moreover, the gray-tone features enable the forming of features having different critical dimensions on a substrate. The gray-tone features may be implemented as sub-resolution features formed by pixellation. The gray-tone features may also be realized by the local size bias of trim features on the trim mask that have dimensions near the resolution limit of the exposure system. The trim mask containing gray-tone features may have regions with different transmissivities or generate varying illumination intensities.

Abstract: A method forms a feature pattern on a substrate by exposing the substrate, using a mask having a pattern of features thereon, with illumination having a first set of settings. The substrate is exposed a second time, using the same mask having the pattern of features thereon, with illumination having a second set of settings. The mask having the pattern of features thereon remains stationary between the two illumination exposures of the substrate.

Abstract: A method forms patterns on a substrate by exposing the substrate a first time and exposing the substrate a second time using a mask containing gray-tone features. The gray-tone features locally adjust an exposure dose in regions corresponding to features defined in the primary exposure. Moreover, the gray-tone features enable the forming of features having different critical dimensions on a substrate. The gray-tone features may be sub-resolution features and formed by pixellation. The trim mask containing gray-tone features may have regions with different transmissivities.

Abstract: A method forms patterns on a substrate by exposing the substrate a first time and exposing the substrate a second time using a mask containing gray-tone features. The gray-tone features locally adjust an exposure dose in regions corresponding to features defined in the primary exposure. Moreover, the gray-tone features enable the forming of features having different critical dimensions on a substrate. The gray-tone features may be implemented as sub-resolution features formed by pixellation. The gray-tone features may also be realized by the local size bias of trim features on the trim mask that have dimensions near the resolution limit of the exposure system. The trim mask containing gray-tone features may have regions with different transmissivities or generate varying illumination intensities.

Abstract: A method forms a feature pattern on a substrate by exposing the substrate, using a mask having a pattern of features thereon, with illumination having a first set of settings. The substrate is exposed a second time, using the same mask having the pattern of features thereon, with illumination having a second set of settings. The mask having the pattern of features thereon remains stationary between the two illumination exposures of the substrate.

Abstract: A method forms a feature pattern on a substrate by exposing the substrate, using a mask having a pattern of features thereon, with illumination having a first set of settings. The substrate is exposed a second time, using the same mask having the pattern of features thereon, with illumination having a second set of settings. The mask having the pattern of features thereon remains stationary between the two illumination exposures of the substrate.

Abstract: A method forms patterns on a substrate by exposing the substrate a first time and exposing the substrate a second time using a mask containing gray-tone features. The gray-tone features locally adjust an exposure dose in regions corresponding to features defined in the primary exposure. Moreover, the gray-tone features enable the forming of features having different critical dimensions on a substrate. The gray-tone features may be sub-resolution features and formed by pixellation. The trim mask containing gray-tone features may have regions with different transmissivities.

Abstract: A method forms patterns on a substrate by exposing the substrate a first time and exposing the substrate a second time using a mask containing gray-tone features. The gray-tone features locally adjust an exposure dose in regions corresponding to features defined in the primary exposure. Moreover, the gray-tone features enable the forming of features having different critical dimensions on a substrate. The gray-tone features may be sub-resolution features and formed by pixellation. The trim mask containing gray-tone features may have regions with different transmissivities.

Abstract: A circuit fabrication and lithography process utilizes a mask including dense repetitive structures of features that result in a wide array of fine densely populated features on the exposed substrate film. Following this, a trimming procedure is performed to remove any unwanted fine patterned features providing multiple trimmed patterns on the substrate. An optional final step adds additional features as well as the interconnect features thus forming a circuit pattern. In this manner, all fine features may be generated using the exact same density of intensity patterns, and therefore, maximum consistency between features is established without the need for optical proximity correction.

Abstract: A mode converter including a silicon waveguide core deposited over a first silicon dioxide cladding layer. The silicon waveguide core is formed such that a first end of the silicon waveguide core has a larger cross-sectional area than a second end of the silicon waveguide core. The silicon waveguide core may include a vertical taper and/or a lateral taper.

Abstract: A method forms a feature pattern on a substrate by exposing the substrate, using a mask having a pattern of features thereon, with illumination having a first set of settings. The substrate is exposed a second time, using the same mask having the pattern of features thereon, with illumination having a second set of settings. The mask having the pattern of features thereon remains stationary between the two illumination exposures of the substrate.

Abstract: A method forms patterns on a substrate by exposing the substrate a first time and exposing the substrate a second time using a mask containing gray-tone features. The gray-tone features locally adjust an exposure dose in regions corresponding to features defined in the primary exposure. Moreover, the gray-tone features enable the forming of features having different critical dimensions on a substrate. The gray-tone features may be sub-resolution features and formed by pixellation. The trim mask containing gray-tone features may have regions with different transmissivities.

Abstract: An apparatus for optical coupling between optical fibers and semiconductor waveguides and method of use thereof. The optical coupler comprises a tapered semiconductor structure having a cross section defined in a plane substantially perpendicular to a direction of propagation of light, which cross section has a dimension accurate to approximately 50 nanometer tolerance. The coupler has an optical index of refraction. The coupler has adjacent thereto material having an optical index less than that of the semiconductor, the adjacent material confining light within the semiconductor structure. In an exemplary embodiment, an optical communication device has two optical couplers disposed one at each end of a semiconductor waveguide to convey an optical communication from a source at one end to receiver at the other. In a further exemplary embodiment, a plurality of optical communication devices are disposed on a single semiconductor substrate.

Abstract: A circuit fabrication and lithography process utilizes a mask including dense repetitive structures of features that result in a wide array of fine densely populated features on the exposed substrate film. Following this, a trimming procedure is performed to remove any unwanted fine patterned features providing multiple trimmed patterns on the substrate. An optional final step adds additional features as well as the interconnect features thus forming a circuit pattern. In this manner, all fine features may be generated using the exact same density of intensity patterns, and therefore, maximum consistency between features is established without the need for optical proximity correction.